The Influence of Operating Parameters on the Biodegradation of

Public Utilities Board, Technology and Water Quality Office, 40 Scotts Road no. 15-01, Environment Building, 228231, Singapore, Earth Tech Engineering...
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Environ. Sci. Technol. 2009, 43, 6646–6654

Influence of Operating Parameters on the Biodegradation of Steroid Estrogens and Nonylphenolic Compounds during Biological Wastewater Treatment Processes YOONG K. K. KOH,† TZE Y. CHIU,‡ ALAN R. BOOBIS,§ MARK D. SCRIMSHAW,| JOHN P. BAGNALL,⊥ ANA SOARES,⊥ S I M O N P O L L A R D , ⊥ E L I S E C A R T M E L L , * ,⊥ AND JOHN N. LESTER⊥ Public Utilities Board, Technology and Water Quality Office, 40 Scotts Road no. 15-01, Environment Building, 228231, Singapore, AECOM DB, Wentworth Business Park, Tankersley, Barnsley, S75 3DL, U.K., Faculty of Medicine, Division of Experimental Medicine and Toxicology, Imperial College London, Hammersmith Campus, London, W12 0NN, U.K., Institute for the Environment, Brunel University, Uxbridge, Middlesex, UB8 3PH, U.K., and Centre for Water Science, School of Applied Sciences, Cranfield University, Bedfordshire, MK43 0AL, U.K.

Received June 19, 2009. Accepted July 10, 2009.

This study investigated operational factors influencing the removal of steroid estrogens and nonylphenolic compounds in two sewage treatment works, one a nitrifying/denitrifying activated sludge plant and the other a nitrifying/denitrifying activated sludge plant with phosphorus removal. Removal efficiencies of >90% for steroid estrogens and for longer chain nonylphenol ethoxylates (NP4-12EO) were observed at both works, which had equal sludge ages of 13 days. However, the biological activity in terms of milligrams of estrogen removed per day per tonne of biomass was found to be 50-60% more efficient in the nitrifying/ denitrifying activated sludge works compared to the works whichadditionallyincorporatedphosphorusremoval.Atemperature reduction of 6 °C had no impact on the removal of free estrogens, but removal of the conjugated estrone-3-sulfate was reduced by 20%. The apparent biomass sorption (LogKp) values were greater in the nitrifying/denitrifying works than those in the nitrifying/denitrifying works with phosphorus removal for both steroid estrogens and nonylphenolic compounds possibly indicating a different cell surface structure and therefore microbial population. The difference in biological activity (mg tonne-1 d-1) identified in this study, of up to seven times, suggests that there is the potential for enhancing the removal of estrogens and nonylphenols if more detailed knowledge of the factors responsible for these differences can be identified and maximized, thus potentially improving the quality of receiving waters. * Corresponding author phone: +44(0) 1234 758366; e-mail: [email protected]. † Public Utilities Board. ‡ AECOM DB. § Imperial College London. | Brunel University. ⊥ Cranfield University. 6646

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Introduction Natural and synthetic estrogens and nonionic surfactants such as nonylphenol polyethoxylates (NPEOs) are endocrine disrupting chemicals (EDCs) that can cause adverse effects on the sexual and reproductive systems in wildlife and fish (1, 2). The effluents discharged from sewage treatment works (STWs) are major sources of these anthropogenic chemicals to the aquatic environment (3). In addition, NPEOs biodegrade during wastewater treatment to generate nonylphenol (NP), the shorter chain mono to triethoxylates (NP1EO, NP2EO, and NP3EO) and a range of carboxylated intermediate byproduct (4, 5) which are more estrogenic than their parent substances (5-8). In the aquatic environment these compounds are amenable to further biotransformation and bioconcentration (9) and may potentially bioaccumulate (10); as a consequence of this behavior complex issues for environmental health arise (2). While secondary biological treatment of wastewater significantly reduces the concentration of some of these compounds, as presently configured and operated, these processes cannot afford adequate protection of the aquatic environment (11). Regulatory authorities are seeking to reduce and ultimately eliminate this problem. In the UK, a £40 million ($75 million) National Demonstration Program (NDP) has been undertaken by the water industry as part of the asset management plan four (AMP4) settlement, initiated by the Environment Agency (EA) of England and Wales to investigate the potential removal of steroid estrogens from final effluents (12). An initial report from the study has concluded that STWs, where treatment involved nitrifying activated sludge, were able to remove steroid estrogens more effectively than those with other biological treatment processes (13). The primary objective of conventional wastewater treatment is the removal of carbon and nitrogen and possibly phosphorus (14), hence current configurations are not designed or operated to remove EDCs (15-17). Tertiary treatment technologies such as granular activated carbon (GAC), advanced oxidation processes (AOPs), and membrane filtration have been suggested to remove these micropollutants (18, 19). However, the presence of high levels of insoluble and dissolved organic matter may interfere with the adsorption process and could therefore result in lower than anticipated removals when GAC is used (20). The same issue also means that employment of AOPs may require high doses of oxidants, thus resulting in increased cost (21). Undoubtedly, advanced treatment technologies will remove these compounds and ameliorate the impact of EDCs on surface waters, but they will inevitably result in significant financial and environmental costs through increased energy consumption and carbon dioxide emissions (21). Environmental sustainability therefore requires the consideration of alternative strategies such as optimisation or modification of existing STWs by determining the operating parameters that govern the removal of these substances within the STW. Several studies have attempted to link certain operating parameters and the removal of EDCs in STWs. In activated sludge systems, solid retention time (SRT) (22-25) and hydraulic retention time (HRT) (3, 26) have both been proposed as factors which may regulate EDC removal, however, explicit information on their precise mode of effect is lacking. There is also no conclusive evidence on the significance of other variables, such as temperature, partitioning to solids and dissolved oxygen concentrations that would inform decisions on the optimisation of STWs for the removal of these chemicals (11, 27). 10.1021/es901612v CCC: $40.75

 2009 American Chemical Society

Published on Web 07/24/2009

FIGURE 1. Schematic diagrams of the two activated sludge sewage treatment works sampled: (A) nitrifying/denitrifying with phosphorus removal (N/DN-P) and (B) nitrifying/denitrifying (N/DN). This study was undertaken to determine the role of operating parameters in the removal and biodegradation of selected steroid estrogens, NPEOs, and their metabolites in two treatment processes: a nitrifying/denitrifying activated sludge plant (N/DN) and a nitrifying/denitrifying activated sludge plant with phosphorus (P) removal (N/DN-P). Such treatment processes are frequently installed at large urban STW where discharges contribute significantly to flows in receiving waters, which are therefore likely to be impacted by discharges of EDCs. The objective of this study was to compare the biological activity of each process, and investigate factors that may influence it, such as organic loading, temperature and dissolved oxygen concentration.

Materials and Methods Sewage Treatment Works. Samples were collected at appropriate stages of the biological treatment processes (after primary sedimentation) at two full-scale STWs (Figure 1), the characteristics of which are described in Table 1. Both STWs were required to nitrify in order to comply with effluent ammonia requirements and the N/DN-P works had an additional anaerobic zone for biological P removal. Chemical precipitation (ferrous) was used following secondary treatment to further reduce final effluent phosphorus concentrations in the N/DN-P works. Sampling Regime. Three separate sampling campaigns were undertaken: at the N/DN works in Summer 2004 and Winter 2006; and finally at the N/DN-P works in Summer 2006. Discrete samples were collected in 2.5 L amber borosilicate glass vessels with Teflon lined caps from 08:00 on a Monday morning through to 12:00 on Friday. The maximum interval between samples was 4-6 h depending on the retention time of the unit processes, for practical reasons such as health and safety and accessibility to the sampling points. The samples were not preserved as they were extracted onto solid phase extraction (SPE) cartridges on site within 15 min of collection. Sampling frequency was such, that in conjunction with the average daily flows,

representative mass balances could be calculated. The monitoring program allowed for coverage of diurnal (day/ night) variation, seasonality (winter/summer) and process type (N/DN and N/DN-P). Little or no precipitation (rain or snow) was experienced during any sampling period. Samples were taken from the settled sewage leading to the activated sludge units, the returned activated sludge (RAS), the final effluents and at the N/DN-P works only, the liquors from sludge thickening treatment containing volatile fatty acids (VFAs) (Figure 1). Analytical Procedure for Steroid Estrogens and Nonylphenolic Compounds. Steroid estrogens and NPEOs were determined in the dissolved and adsorbed phases in all samples. Methodology for the determination of the natural and synthetic steroid estrogens: estrone (E1); 17β-estradiol (E2); estriol (E3); sulfate conjugate of estrone (E1-3S); and 17R-ethinylestradiol (EE2) in the dissolved phase (28) and on solids (29) has previously been reported. Estrogens are predominantly excreted as either glucuronide or sulfate conjugates, although only estrone 3-sulfate (E1-3S) has been detected in UK sewage (30), probably as a result of the predominance of this conjugate in urine and the rapid deconjugation of the glucuronides (31). Therefore, only this conjugate was analyzed. The nonylphenolic compounds: nonylphenols, nonylphenol polyethoxylates (NPEO), and nonylphenol ethoxycarboxylates (NPEC) in the dissolved phase were determined by the method of Koh et al. (32). Methodology for the determination of these compounds on the solid phase, along with full descriptions of all methods and their performance are provided in the Supporting Information. In summary, 1 L sewage samples for both steroid estrogens and NPEOs were filtered through glass fiber GF/C filters (VWR International, Leicestershire, UK) prior to solid phase extraction on separate tC18 SPE cartridges. For the dissolved phase, steroid estrogens were extracted from the tC18 cartridges followed by two further sample cleanup stages and quantification using LC/ESI(-)/MS/MS. The nonylphenolic compounds were eluted from the tC18 cartridges and VOL. 43, NO. 17, 2009 / ENVIRONMENTAL SCIENCE & TECHNOLOGY

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TABLE 1. Overview of the Operating Parameters of the Two Sewage Treatment Worksa N/DN

N/DN-P

operating parameters

Summer 2004

Winter 2006

Summer 2006

biological process process technology PE Q activated sludge process (m3 d-1) HRT θτ (h) SRT θc (d) DO (g m-3) MLVSS (g m-3) F:M ratio (g BOD. g-1 MLVSS.d-1) pH Trade input Ambient (°C) Sewage (°C)

nitrifying/denitrifying anoxic/aerobic 150 000 12 000 13.6 (0.6d) 13 1.4 2740

nitrifying/denitrifying anoxic/aerobic 150 000 17 200 10.2 (0.4d) 13 3.2 3282

nitrifying/denitrifying/p-removal anoxic/anaerobic/aerobic 250 323 44 000 12.1 (0.5d) 9-13 1.8 4971

0.09

0.1

0.05

COD (g m-3) BOD (g m-3) NH4-N (g m-3) NO3-N (g m-3) P (g m-3) TSS (g m-3)

252 151 34.5 3 n/d 266

COD (g m-3) BOD (g m-3) NH4-N (g m-3) NO3-N (g m-3) P (g m-3) TSS (g m-3)

40.1 4